Scattering and sublimation: a multi-scale view of µm-sized dust in the inclined disc of HD 145718
Davies, CL; Rich, EA; Harries, TJ; et al.Monnier, JD; Laws, ASE; Andrews, SM; Bae, J; Wilner, DJ; Anugu, N; Ennis, J; Gardner, T; Kraus, S; Labdon, A; le Bouquin, J-B; Lanthermann, C; Schaefer, GH; Setterholm, BR; ten Brummelaar, T
Date: 28 January 2022
Journal
Monthly Notices of the Royal Astronomical Society
Publisher
Oxford University Press (OUP) / Royal Astronomical Society
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Abstract
We present multi-instrument observations of the disc around the Herbig Ae star, HD 145718, employing geometric and Monte Carlo radiative transfer models to explore the disc orientation, the vertical and radial extent of the near infrared (NIR) scattering surface, and the properties of the dust in the disc surface and sublimation rim. ...
We present multi-instrument observations of the disc around the Herbig Ae star, HD 145718, employing geometric and Monte Carlo radiative transfer models to explore the disc orientation, the vertical and radial extent of the near infrared (NIR) scattering surface, and the properties of the dust in the disc surface and sublimation rim. The disc appears inclined at 67−71◦, with position angle, PA= −1.0 − 0.6◦, consistent with previous estimates. The NIR scattering surface extends out to ∼ 75au and we infer an aspect ratio, hscat(r)/r ∼ 0.24 in J-band; ∼ 0.22 in H-band. Our GPI images and VLTI+CHARA NIR interferometry suggest that the disc surface layers are populated by grains λ/2π in size, indicating these grains are aerodynamically supported against settling and/or the density of smaller grains is relatively low. We demonstrate that our geometric analysis provides a reasonable assessment of the height of the NIR scattering surface at the outer edge of the disc and, if the inclination can be independently constrained, has the potential to probe the flaring exponent of the scattering surface in similarly inclined (i 70◦) discs. In re-evaluating HD 145718’s stellar properties, we found that the object’s dimming events -previously characterised as UX Or and dipper variability -are consistent with dust occultation by grains larger, on average, than found in the ISM. This occulting dust likely originates close to the inferred dust sublimation radius at 0.17au.
Physics and Astronomy
Faculty of Environment, Science and Economy
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